Methods and devices for localized inhibition of inflammation by ablation

ABSTRACT

Provided herein are methods, systems, and devices for increasing IL-10 expression, inhibiting inflammation, and treating inflammatory conditions using thermal ablation.

RELATED APPLICATIONS

The present application claims priority to U.S. Provisional Patent Application No. 61/639,682, filed Apr. 27, 2012, entitled “METHODS AND DEVICES FOR LOCALIZED INHIBITION OF INFLAMMATION BY THERMAL ABLATION,” the disclosure of which is incorporated by reference herein in its entirety.

BACKGROUND

The inflammatory response is a complex defensive reaction in vertebrates to infection or injury caused by chemical agents, pathogens, or physical stresses. The complexity of the inflammatory response is illustrated by the “immune cascade” that occurs in response to infection. Macrophages and dendritic cells at the insult site express surface receptors that identify infectious agents. Upon encountering an infectious agent, these cells release inflammatory mediators (soluble factors) such as cytokines and chemokines, which cause vasodilation and exudation of plasma proteins and fluid into the affected tissue. Inflammatory mediators also attract and facilitate transport of leukocytes such as neutrophils, lymphocytes, monocytes, and macrophages from the blood vessels into the affected tissue. The inflammatory response is further assisted by the activation of cellular biochemical cascade systems, including the complement, coagulation, fibrinolytic, and kinin systems.

Acute inflammation is an essential component of wound healing, but chronic inflammation can cause tissue destruction and lead to conditions such as cardiovascular disease, neurodegeneration, and autoimmunity. Inflammatory conditions associated with chronic inflammation are highly prevalent, creating a significant economic burden and leading to low quality of life for affected individuals. A variety of anti-inflammatory agents are available for treating these conditions, but most of these agents are administered systemically and are associated with side effects such as increased infection.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1: Examples of IL-10 detection methods: antibody-based detection (upper and middle panel), and activity-based detection (lower panel).

FIG. 2: Illustrative digital and analog outputs for displaying a detectable signal generated by the interaction of IL-10 with a capture or detection agent.

FIG. 3: Quantum dot system for generation of a detectable signal following binding of IL-10 to an affinity ligand capture agent.

FIG. 4: Illustrative IL-10 capture methods: removal from ablation site and sequestration in a capture compartment for analysis in vivo or ex vivo (upper panel), balloon-based/semi-permeable filtering device with antibody based/immuno-electrochemical technology embedded within for capture and analysis in vivo or ex vivo (lower panel).

FIG. 5: Average kidney NE levels post-ablation.

FIG. 6: Upregulation of IL-10 (A) 10 minutes, (B) 24 hours, and (C) 7 days post-ablation.

FIG. 7: Illustration of representative electrochemical immunosensor protocols.

FIG. 8: Effect of heat, inflammatory conditions, and a combination of heat and inflammatory conditions on IL-10 expression.

FIG. 9: Change in IL-7 expression following treatment with heat and inflammation or inflammation only.

FIG. 10: Change in IFNB1 expression following treatment with heat and inflammation or inflammation only.

FIG. 11: Change in IL-11 expression following treatment with heat and inflammation or inflammation only.

FIG. 12: Change in CXCL2 expression following treatment with heat and inflammation or inflammation only.

FIG. 13: Change in CXCL11 expression following treatment with heat and inflammation or inflammation only.

FIG. 14: Change in CD70 expression following treatment with heat and inflammation or inflammation only.

FIG. 15: Change in CASP7 expression following treatment with heat and inflammation or inflammation only.

FIG. 16: Change in CASP10 expression following treatment with heat and inflammation or inflammation only.

FIG. 17: Embodiments of a system for carrying out the methods disclosed herein.

DETAILED DESCRIPTION

The present technology is directed to methods, systems, devices, and kits for increasing IL-10 expression levels at or near a target site using ablation, as well as to methods, systems, devices, and kits for inhibiting inflammation at or near a target site and treating inflammatory conditions by increasing IL-10 expression. Although many of the embodiments are described with respect to methods, systems, devices, and kits for treating inflammatory conditions using thermal ablation, other applications (e.g., treatment of other conditions associated with decreased IL-10 expression, use of non-thermal ablative modalities) and other embodiments in addition to those described herein are within the scope of the technology. Additionally, several other embodiments of the technology can have different configurations, components, or procedures than those described herein. A person of ordinary skill in the art, therefore, will accordingly understand that the technology can have other embodiments with additional elements, or the technology can have other embodiments without several of the features shown and described below.

IL-10 is a secreted anti-inflammatory cytokine with pleiotropic effects in immunoregulation and inflammation (Zager Am J Physiol Renal Physiol 301:F1334 (2011); Lu Curr Med Chem 17:957 (2010)). IL-10 is produced by T cells and plays an essential role in controlling inflammation and instructing adaptive immune responses (Hedrich Immunol Res 47:185 (2010)). IL-10 inhibits macrophage and/or dendritic cell activation and maturation and T cell proliferation, in part by antagonizing the expression of MHC class II and the co-stimulatory molecules B7.1/B7.2 (CD80/CD86) and the proinflammatory cytokines IL-1β, IL-6, IL-8, TNF-α, and IL-12 (Hedrich).

IL-10 also plays a key role in balancing T helper (Th) 1 and 2 responses. The Th1 response is activated in response to intracellular agents, while the Th2 response is activated in response to extracellular agents. Although a healthy immune system can respond to either type of infectious agent, many chronic inflammatory conditions (e.g., rheumatoid arthritis (RA), multiple sclerosis (MS), and Crohn's disease) are skewed towards a Th1 response. IL-10 can serve to overcome this imbalance by inducing Th2 production and inhibiting Th1 proliferation by antagonizing expression of IL-12.

Without the inhibitory effects of IL-10, acute inflammation can become chronic inflammation, leading to tissue destruction and the onset of inflammatory conditions. Accordingly, dysregulation of IL-10 has been associated with increased susceptibility to many infectious and autoimmune diseases in mammals.

Given the key role of IL-10 in inhibiting inflammation, the molecule provides an attractive target for anti-inflammatory therapeutics. However, previous IL-10 treatment modalities lack a simple mechanism for increasing IL-10 concentration at a localized target site.

Thermal ablation is frequently used to remove or inactivate a target body tissue by applying targeted heat (hyperthermal ablation) or cold (hypothermal ablation). Examples of hyperthermal ablation techniques include the use of monopolar or bipolar radio frequency (RF) energy, microwave energy, laser light or optical energy, ultrasound energy (e.g., intravascularly delivered ultrasound, extracorporeal ultrasound, high frequency ultrasound (HIFU)), magnetic energy, and direct heat energy. Examples of hypothermal ablation techniques include the use of cryotherapeutic energy. Hyperthermal ablation has been used to treat a variety of conditions, including cancer of the lung, liver, kidney, and bone, and conditions associated with electrical conduction in the heart such as arrhythmia.

Thermal ablation can also be used to partially or completely disrupt the ability of a nerve to transmit a signal. For example, intravascular devices that reduce sympathetic nerve activity by applying RF energy to a target site in the renal artery have recently been shown to reduce blood pressure in patients with treatment-resistant hypertension. The renal sympathetic nerves arise from T10-L2 and follow the renal artery to the kidney. The sympathetic nerves innervating the kidneys terminate in the blood vessels, the juxtaglomerular apparatus, and the renal tubules. Stimulation of renal efferent nerves results in increased renin release (and subsequent renin-angiotensin-aldosterone system (RAAS) activation) and sodium retention and decreased renal blood flow. These neural regulation components of renal function are considerably stimulated in disease states characterized by heightened sympathetic tone and likely contribute to increased blood pressure in hypertensive patients. The reduction of renal blood flow and glomerular filtration rate as a result of renal sympathetic efferent stimulation is likely a cornerstone of the loss of renal function in cardio-renal syndrome (i.e., renal dysfunction as a progressive complication of chronic heart failure).

As disclosed herein, thermal ablation of renal sympathetic nerves has been found to unexpectedly increase local IL-10 expression. This increase was observed at 10 minutes, 24 hours, and 7 days post-ablation, indicating that IL-10 levels remain elevated for an extended period following ablation. Based on this finding, methods, systems, and devices are provided herein for increasing IL-10 expression and inhibiting inflammation in a targeted manner, and for treating various inflammatory conditions by increasing IL-10 levels.

Specific details of several embodiments of the technology are described below with reference to FIGS. 1-17. Although many of the embodiments are described below with respect to methods, systems, and devices for inducing IL-10 expression, inhibiting inflammation, and treating inflammatory conditions using thermal ablation, other applications (e.g., treating other conditions that respond to increased IL-10 levels, using other techniques such as non-thermal neuromodulation to increase IL-10 expression) and other embodiments in addition to those described herein are within the scope of the technology. Additionally, several other embodiments of the technology can have different configurations, components, or procedures than those described herein. A person of ordinary skill in the art, therefore, will accordingly understand that the technology can have other embodiments with additional elements, or the technology can have other embodiments without several of the features shown and described below with reference to FIGS. 1-17.

Disclosed herein are several embodiments of methods for increasing IL-10 expression at or near a target tissue site, inhibiting inflammation at or near a target site, and treating an inflammatory condition in a subject in need thereof using thermal ablation. The methods disclosed herein represent a significant improvement over conventional approaches and techniques in that they allow for more specific targeting of IL-10 therapy and localized inhibition of inflammation. Further provided herein are systems and devices for use in conjunction with the disclosed methods.

Provided herein in certain embodiments are methods for increasing IL-10 expression levels at or near a target site in a subject by performing a thermal ablation procedure at or near the target site. In certain of these embodiments, IL-10 expression levels are increased within 30 minutes following the thermal ablation procedure, and in certain of these embodiments IL-10 expression levels are increased within 10 minutes following the thermal ablation procedure. In certain embodiments, IL-10 expression is increased at one or more specified timepoints following ablation, and in certain of these embodiments IL-10 expression is increased at 10 minutes, 24 hours, or 7 days following ablation. In certain embodiments, the thermal ablation procedure is carried out using monopolar or bipolar RF energy, microwave energy, laser light or optical energy, ultrasound energy (e.g., intravascularly delivered ultrasound, extracorporeal ultrasound, HIFU), magnetic energy, direct heat energy, or cryotherapeutic energy. In certain embodiments, the target site is in a renal blood vessel, and in certain of these embodiments the thermal ablation procedure targets renal sympathetic nerves.

Provided herein in certain embodiments are methods for inhibiting inflammation at or near a target site in a subject by performing a thermal ablation procedure at or near the target site, wherein the procedure increases IL-10 expression levels at or near the site and thereby inhibits inflammation. In certain of these embodiments, IL-10 expression levels are increased within 30 minutes following the thermal ablation procedure, and in certain of these embodiments IL-10 expression levels are increased within 10 minutes following the thermal ablation procedure. In certain embodiments, IL-10 expression is increased at one or more specified timepoints following ablation, and in certain of these embodiments IL-10 expression is increased at 10 minutes, 24 hours, or 7 days following ablation. In certain embodiments, the thermal ablation procedure is carried out using monopolar or bipolar RF energy, microwave energy, laser light or optical energy, ultrasound energy (e.g., intravascularly delivered ultrasound, extracorporeal ultrasound, HIFU), magnetic energy, direct heat energy, or cryotherapeutic energy. In certain embodiments, the target site is in a renal blood vessel, and in certain of these embodiments the thermal ablation procedure targets renal sympathetic nerves.

Provided herein in certain embodiments are methods for treating an inflammatory condition in a subject by performing a thermal ablation procedure, wherein the procedure increases IL-10 expression levels and thereby inhibits inflammation. In certain of these embodiments, IL-10 expression levels are increased within 30 minutes following the thermal ablation procedure, and in certain of these embodiments IL-10 expression levels are increased within 10 minutes following the thermal ablation procedure. In certain embodiments, IL-10 expression is increased at one or more specified timepoints following ablation, and in certain of these embodiments IL-10 expression is increased at 10 minutes, 24 hours, or 7 days following ablation. In certain embodiments, the thermal ablation procedure is carried out using monopolar or bipolar RF energy, microwave energy, laser light or optical energy, ultrasound energy (e.g., intravascularly delivered ultrasound, extracorporeal ultrasound, HIFU), magnetic energy, direct heat energy, or cryotherapeutic energy. In certain embodiments, the target site is in a renal blood vessel, and in certain of these embodiments the thermal ablation procedure targets renal sympathetic nerves.

Provided herein in certain embodiments are devices, systems, and kits for carrying out the methods disclosed herein.

In certain embodiments, the methods provided herein comprise performing thermal ablation, thereby increasing IL-10 expression at or near the target site. An increase in IL-10 expression may refer to an increase in IL-10 mRNA or protein level or an increase in IL-10 secretion. In certain embodiments, thermal ablation results in an increase in IL-10 activity at or near a target site in addition to or in lieu of an increase in IL-10 expression. In certain embodiments, thermal ablation may be repeated one or more times at various intervals until a desired IL-10 expression level or another therapeutic benchmark is reached.

In certain embodiments of the methods provided herein, thermal ablation results in an increase in IL-10 levels over a specific timeframe. In certain of these embodiments, IL-10 levels are increased over an acute timeframe, e.g., within 30 minutes or less following ablation. For example, IL-10 levels may be increased at 30 seconds, 1 minute, 2 minutes, 5 minutes, 10 minutes, 15 minutes, 20 minutes, or 30 minutes post-ablation. In certain embodiments, IL-10 levels may be elevated at one or more timepoints beyond an acute timeframe. In these embodiments, IL-10 levels may be elevated at or near the target site at 1 hour or more, 2 hours or more, 6 hours or more, 12 hours or more, 24 hours or more, 48 hours or more, 72 hours or more, or a week or more after the ablation procedure. In certain embodiments where IL-10 levels are increased over an acute timeframe, levels remain increased beyond the acute timeframe. In other embodiments, IL-10 levels are elevated during the acute timeframe, but drop back to a baseline level or below before the end of the acute timeframe.

In certain embodiments, the methods disclosed herein may comprise an additional step of measuring IL-10 expression levels, and in certain of these embodiments the methods further comprise comparing the IL-10 expression level to a baseline IL-10 expression level. Such measurements and comparisons can be used to monitor therapeutic efficacy and to determine when and if to repeat the ablation procedure. In certain embodiments, a baseline IL-10 expression level is derived from the subject undergoing treatment. For example, baseline IL-10 expression may be measured in the subject at one or more timepoints prior to thermal ablation. Baseline IL-10 value may represent IL-10 expression at a specific timepoint before thermal ablation, or it may represent an average expression level at two or more timepoints prior to thermal ablation. In certain embodiments, the baseline value is based on IL-10 expression at or near the target site immediately prior to thermal ablation (e.g., after the subject has already been catheterized). Alternatively, a baseline value may be derived from a standard value for IL-10 expression observed across the population as a whole or across a particular subpopulation. In certain embodiments, post-ablation IL-10 levels are measured in an acute timeframe, i.e., while the subject is still catheterized and/or under anesthesia.

In certain embodiments of the methods provided herein, the increase in IL-10 expression level post-ablation may result in an expression level at or near the target site that is greater (e.g., two-fold or greater, three-fold or greater, five-fold or greater, etc.) than a baseline IL-10 expression level at one or more timepoints post-ablation. For example, IL-10 levels may be elevated to a level two-fold or greater than the baseline expression level at one or more timepoints within an acute timeframe, e.g., within 30 minutes or less following ablation.

In certain embodiments of the methods provided herein, the methods are designed to increase IL-10 expression to a target level. In these embodiments, the methods include a step of measuring IL-10 levels post-ablation and comparing the resultant expression level to a baseline expression level as discussed above. In certain of these embodiments, the ablation step is repeated until the target IL-10 level is reached. In other embodiments, the methods are simply designed to increase IL-10 above a baseline level without requiring a particular target expression level.

The methods disclosed herein result in a localized increase in IL-10 expression, i.e., at or near a target site. In certain embodiments, the methods may further result in an increase in IL-10 expression levels at locations remote to the target site. In certain of these embodiments, IL-10 expression levels may be elevated systemically, such that they can be detected by a urine or blood draw from a subject.

In those embodiments of the methods disclosed herein that are directed to the treatment of an inflammatory condition, the condition may be any disease or disorder associated with inflammation. Such diseases or disorders include, for example, arthritides such as RA or osteoarthritis, MS, inflammatory bowel diseases such as Crohn's disease or ulcerative colitis, Alzheimer's disease, sickle cell disease, atherosclerosis, Reiter's disease, psoriasis, ankylosing spondylitis, dermatitis, systemic lupus erythematosus inflammatory neuropathy, inflammatory myopathy, Sjögrens syndrome, diabetes, and asthma.

Treatment of an inflammatory condition may refer to preventing the condition, slowing the onset or rate of development of the condition, reducing the risk of developing the condition, preventing or delaying the development of symptoms associated with the condition, reducing or ending symptoms associated with the condition, generating a complete or partial regression of the condition, or some combination thereof.

A target site may be located in any target tissue that can be subjected to thermal ablation. As disclosed herein, thermal ablation of renal efferent nerves was shown to increase IL-10 expression at renal target sites. Thermal ablation is likewise expected to result in a similar increase in IL-10 expression levels in other tissue types. In certain embodiments of the methods disclosed herein, the target site may depend on the specific condition being treated. In certain embodiments, a target site is located in a target tissue that is currently experiencing an inflammatory response, is at risk for experiencing an inflammatory response, or has experienced an inflammatory response previously. In certain embodiments, a target site may exhibit elevated levels of one or more pro-inflammatory cytokines such as TNF-α or other inflammatory markers such as sPLA₂. In certain embodiments, the increase in IL-10 expression following thermal ablation correlates with a decrease in levels of one or more of these pro-inflammatory cytokines or inflammatory markers. In those embodiments of the methods disclosed herein that are directed to the treatment of an inflammatory condition, the target site may depend on the specific disease being treated.

In certain embodiments of the treatment methods disclosed herein, the inflammatory condition being treated is a renal inflammatory condition. For example, the inflammatory condition may be a nephritis such as glomerulonephritis or interstitial nephritis caused by toxins, infections, or autoimmune conditions (e.g., lupus nephritis). In certain of these embodiments, the target site is located in the kidneys. For example, thermal ablation may target one or more renal nerves, including for example nerves proximate to the renal artery.

In certain embodiments of the treatment methods disclosed herein, the inflammatory condition being treated is a gastrointestinal inflammatory condition such as Crohn's disease, gastritis, ulcerative colitis, or gastrointestinal dysmotility. In certain of these embodiments, the target site is located in the gastrointestinal tract. For example, the target site may be located in the stomach, small intestine, large intestine, pancreas, or gut-associated lymphoid tissue (GALT). In these embodiments, thermal ablation may target one or more gastrointestinal nerves, including for example nerves proximate to the superior or inferior mesenteric artery, the superior or inferior mesenteric vein, or another portion of a vessel or duct of a gastrointestinal organ. In other embodiments, thermal ablation may target the adrenal gland or nerves proximate thereto.

In certain embodiments of the treatment methods disclosed herein, the inflammatory condition being treated is an arthritic condition such as rheumatoid arthritis. In certain of these embodiments, the target site may be located in the spleen, thymus, or lymph nodes, or nerves proximate to and/or serving arthritis-affected joints.

The methods disclosed herein may use any thermal ablation technique known in the art, including the use of monopolar or bipolar RF energy, microwave energy, laser light or optical energy, ultrasound energy (e.g., intravascularly delivered ultrasound, extracorporeal ultrasound, HIFU), magnetic energy, direct heat energy, cryotherapeutic energy, or a combination thereof. Alternatively or in addition to these techniques, the methods may utilize one or more non-thermal neuromodulatory techniques. For example, the methods may utilize sympathetic nervous system (SNS) denervation by removal of target nerves, injection of target nerves with a destructive drug or pharmaceutical compound, or treatment of the target nerves with non-thermal energy modalities. In certain embodiments, the magnitude or duration of the increase in IL-10 expression may vary depending on the specific technique being used.

Thermal ablation may be carried out using any ablation device known in the art. In certain embodiments, ablation may be carried out using a device that is in direct or close contact with a target site. In certain of these embodiments, the ablation device may access the target site via a minimally invasive route, for example via an intravascular pathway such as a femoral, brachial, or radial point of entry. In these embodiments, the ablation device and related components may have size, flexibility, torque-ability, kink resistance, or other characteristics suitable for accessing narrow or difficult to reach portions of vessels. In other embodiments, the target site may be accessed using an invasive direct access technique. In certain embodiments, the device may be used externally, i.e., without direct or close contact to the target site.

In certain embodiments, an ablation device for use in the methods disclosed herein may combine two or more energy modalities. The device may include both a hyperthermic source of ablative energy and a hypothermic source, making it capable of, for example, performing both RF ablation and cryoablation. The distal end of the treatment device may be straight (for example, a focal catheter), expandable (for example, an expanding mesh or cryoballoon), or have any other configuration (e.g., a helical or spiral coil). Additionally or alternatively, the treatment device may be configured to carry out one or more non-thermal neuromodulatory techniques. For example, the device may comprise a means for diffusing a drug or pharmaceutical compound onto the target treatment area (for example, a distal spray nozzle).

In those embodiments of the methods disclosed herein that include a step of measuring IL-10 expression levels before or after thermal ablation, such measurement can be carried out using any method known in the art. For example, the measurement can utilize one or more capture or detection agents that specifically bind IL-10, such as an antibody or epitope-binding portion thereof, an IL-10 receptor or a portion thereof, or a nucleic acid complementary to all or a portion of the IL-10 mRNA sequence. FIG. 1 illustrates the use of a labeled antibody to bind and detect IL-10 at the artery wall (upper panel) or in circulation (middle panel). In other examples, measurement of IL-10 expression may utilize a detection agent that has a functional interaction with IL-10. For example, the detection agent may be a substrate for IL-10 or an enzyme or catalytic antibody for which IL-10 is a substrate. FIG. 1 illustrates the use of a detection agent (represented by scissors) that functions to cleave off a portion of IL-10. In still other examples, measurement of IL-10 may be carried out using imaging/spectroscopy techniques that allow IL-10 levels to be assessed in a non-invasive manner or by tissue sampling.

Capture or detection agents for use detecting and measuring IL-10 expression may be in solution, or they may be immobilized on a surface such as a bead, resin, or one or more surfaces of an ablation or other treatment device, a component thereof, or a separate capture device. Examples of suitable resins include, for example, hydrophobic resins, cation/anion exchange resins (e.g., carboxymethyl, sulfopropyl/diethylamine), immobilized metal affinity chromatography (IMAC) resins, and polar chromatographic resins (e.g., silica gel). In those embodiments wherein capture or detection agents are immobilized on one or more surfaces of a treatment device, a component thereof, or a separate capture device, the capture or detection agents may be on the outside of the device, i.e., in direct contact with arterial blood or the artery wall. In other embodiments, the capture or detection agents may be on an internal surface, such as the interior of a catheter or a capture compartment.

In certain embodiments, binding of IL-10 to a capture agent and/or interaction of IL-10 with a detection agent results in a quantifiable signal. This quantifiable signal may be, for example, a colorimetric, fluorescent, heat, energy, or electric signal. In certain embodiments, this signal may be transduced to an external visual output device (see, e.g., FIG. 2). In certain embodiments, a capture or detection agent may be labeled, such as for example with an enzymatic or radioactive label. A capture or detection agent may be a binding substrate for a secondary capture agent, such as a labeled antibody.

In certain embodiments, binding of IL-10 to a capture agent results in a signal that can be transduced to an external monitoring device. For example, binding of IL-10 to a capture or detection agent may be detected using a high sensitivity fluorescence technique such as a resonance energy transfer method (e.g., Forster resonance energy transfer, bioluminescence resonance energy transfer, or surface plasmon resonance energy transfer). FIG. 3 illustrates a quantum dot embodiment for generating a signal based on binding of IL-10 to an affinity ligand capture agent (e.g., an antibody, peptide, small molecule drug, or inhibitor). Quantum dots are nanometer sized semiconductor crystals that fluoresce when excited with the proper frequency of light (see, e.g., Xing Nat Protoc 2:1152 (2007)). The emitted light is tuned by the size of the nanocrystal, and excitation frequencies range from near IR to UV. Dynamic visualization through skin has been demonstrated in animals using near IR radiation.

In certain embodiments of the methods disclosed herein, determination of baseline and/or post-ablation IL-10 expression or activity is carried out using any immunoassay-based method. For example, IL-10 levels may be determined using an electrochemical immunosensor (see, e.g., FIG. 7), which provides concentration-dependent signaling (see, e.g., Centi Bioanalysis 1:1271 (2009); Rusling Analyst 135:2496 (2010)). Antibodies for use in an immunoassay-based determination of IL-10 level or activity may be labeled or unlabeled.

In certain embodiments, determination of baseline and/or post-ablation IL-10 level or activity takes place in vivo. In these embodiments, the determination may be carried out using the same device that is used to carry out ablation, or a component attached to the ablation device. Alternatively, determination of IL-10 level or activity may be carried out using a separate device. In certain of these embodiments, the separate device is delivered to the ablation site via the same catheter used to deliver the treatment device. In other embodiments, determination of baseline and/or post-ablation IL-10 level or activity takes place ex vivo.

In certain embodiments, the interaction between IL-10 and a capture or detection agent takes place at or near the ablation site. In certain of these embodiments, IL-10 binds to a capture or detection agent in the bloodstream or at the surface of the arterial wall. In these embodiments, the capture or detection agent may be in solution (i.e., in the bloodstream) or immobilized to a surface that is contact with the bloodstream and/or arterial wall. For example, a device or component thereof in which a capture or detection agent is integrated may be a balloon coated with one or more detection molecules that inflates to touch the ablated artery wall (see, e.g., FIG. 4, lower panel). Captured biomarkers may be detected in vivo, or the balloon-based device may be removed for biomarker detection ex vivo.

In other embodiments, the interaction between IL-10 and a capture or detection agent takes place away from the ablation site. For example, IL-10 may be removed from an ablation site and sequestered in a capture compartment (see, e.g., FIG. 4, upper panel). Removal from the ablation site may utilize one or more filters. For example, a first filter at the distal end of a capture compartment may be selected such that it allows passage of IL-10 into the capture compartment while preventing passage of other biomolecules. A second filter at a proximal end of the capture component may be selected such it prevents passage of IL-10 out of the capture compartment while allowing blood to flow out of the capture compartment. Through the use of one or more filters, IL-10 may be concentrated within the capture compartment. Alternatively or in addition to the use of filters, one or more additional steps may be taken to concentrate IL-10 in the capture compartment prior to or simultaneous with contacting of IL-10 with capture or target agents. For example, IL-10 may be concentrated using beads. In certain embodiments that utilize a capture compartment, IL-10 is contacted with capture or detection agents in the capture compartment while still in the body. Alternatively, the capture compartment may be removed from the body prior to contacting IL-10 with capture or detection agents.

In one embodiment of the methods disclosed herein, an RF ablation catheter is used as the treatment device. The RF ablation catheter is advanced directly to a target site such as the renal artery or a specific location within the renal artery via an intravascular pathway. In this embodiment, the RF ablation catheter comprises an elongate shaft having a distal end and a plurality of electrodes (as the treatment elements) coupled thereto. An introducer sheath may be used to facilitate advancement of the device to the target site. Further, image guidance, such as computed tomography (CT) fluoroscopy, intravascular ultrasound (IVUS), optical coherence tomography (OCT), or other suitable guidance modality, or combinations thereof, may be used to aid the clinician's manipulation. In certain embodiments, image guidance components (for example, IVUS or OCT) may be incorporated into the treatment device itself. Once the treatment device is adequately positioned in contact or close proximity to the target site, the device is activated and RF energy is applied from the one or more electrodes, effectively ablating the arterial tissue. Ablation continues for a predetermined amount of time, or until visualization of the treatment area shows sufficient ablation. The RF ablation catheter is then removed from the patient. In those embodiments wherein IL-10 levels are measured subsequent to ablation, a sample for IL-10 expression measurement may be obtained using the device or a component attached thereto prior to removal. In other embodiments, an introducer sheath may be left in place following catheter removal, and a sampling device may be advanced to the target site.

In one embodiment, the methods disclosed herein utilize a neuromodulation system as set forth in FIG. 17. This neuromodulation system 100 (“system 100”) can include a treatment device 102 for carrying out ablation, an energy source or console 104 (e.g., an RF energy generator, a cryotherapy console, etc.), and a cable 106 extending between the treatment device 102 and the console 104. The treatment device 102 can include a handle 108, a therapeutic element 110, and an elongated shaft 112 extending between the handle 108 and the therapeutic element 110. The shaft 112 can be configured to locate the therapeutic element 110 intravascularly or intraluminally at a treatment location, and the therapeutic element 110 can be configured to provide or support therapeutically-effective neuromodulation at the treatment location. In certain embodiments, the shaft 112 and the therapeutic element 110 can be 3, 4, 5, 6, or 7 French or another suitable size. Furthermore, the shaft 112 and the therapeutic element 110 can be partially or fully radiopaque and/or can include radiopaque markers corresponding to measurements, e.g., every 5 cm. In certain embodiments, the treatment device comprises an optional monitoring or sampling component for evaluating changes in IL-10 expression.

Intravascular delivery can include percutaneously inserting a guide wire (not shown) within the vasculature and moving the shaft 112 and the therapeutic element 110 along the guide wire until the therapeutic element 110 reaches the treatment location. For example, the shaft 112 and the therapeutic element 110 can include a guide-wire lumen (not shown) configured to receive the guide wire in an over-the-wire (OTW) or rapid-exchange configuration (RX). Other body lumens (e.g., ducts or internal chambers) can be treated, for example, by non-percutaneously passing the shaft 112 and therapeutic element 110 through externally accessible passages of the body or other suitable methods. In some embodiments, a distal end of the therapeutic element 110 can terminate in an atraumatic rounded tip or cap (not shown). The treatment device 102 can also be a steerable or non-steerable catheter device configured for use without a guide wire.

The therapeutic element 110 can have a single state or configuration, or it can be convertible between a plurality of states or configurations. For example, the therapeutic element 110 can be configured to be delivered to the treatment location in a delivery state and to provide or support therapeutically-effective neuromodulation in a deployed state. In these and other embodiments, the therapeutic element 110 can have different sizes and/or shapes in the delivery and deployed states. For example, the therapeutic element 110 can have a low-profile configuration in the delivery state and an expanded configuration in the deployed state. In another example, the therapeutic element 110 can be configured to deflect into contact with a vessel wall in a delivery state. The therapeutic element 110 can be converted (e.g., placed or transformed) between the delivery and deployed states via remote actuation, e.g., using an actuator 114 of the handle 108. The actuator 114 can include a knob, a pin, a lever, a button, a dial, or another suitable control component. In other embodiments, the therapeutic element 110 can be transformed between the delivery and deployed states using other suitable mechanisms or techniques.

In some embodiments, the therapeutic element 110 can include an elongated member (not shown) that can be configured to curve (e.g., arch) in the deployed state, e.g., in response to movement of the actuator 114. For example, the elongated member can be at least partially helical/spiral in the deployed state. In other embodiments, the therapeutic element 110 can include a balloon (not shown) that can be configured to be at least partially inflated in the deployed state. An elongated member, for example, can be well suited for carrying one or more electrodes or transducers and for delivering electrode-based or transducer-based treatment. A balloon, for example, can be well suited for containing refrigerant (e.g., during or shortly after liquid-to-gas phase change) and for delivering cryotherapeutic treatment. In some embodiments, the therapeutic element 110 can be configured for intravascular, transvascular, intraluminal, and/or transluminal delivery of chemicals. For example, the therapeutic element 110 can include one or more openings (not shown), and chemicals (e.g., drugs or other agents) can be deliverable through the openings. For transvascular and transluminal delivery, the therapeutic element 110 can include one or more needles (not shown) (e.g., retractable needles) and the openings can be at end portions of the needles.

The console 104 is configured to control, monitor, supply, or otherwise support operation of the treatment device 102. In other embodiments, the treatment device 102 can be self-contained and/or otherwise configured for operation without connection to the console 104. As shown in FIG. 17, the console 104 can include a primary housing 116 having a display 118. The system 100 can include a control device 120 along the cable 106 configured to initiate, terminate, and/or adjust operation of the treatment device 102 directly and/or via the console 104. In other embodiments, the system 100 can include another suitable control mechanism. For example, the control device 120 can be incorporated into the handle 108. The console 104 can be configured to execute an automated control algorithm 122 and/or to receive control instructions from an operator. Furthermore, the console 104 can be configured to provide feedback to an operator before, during, and/or after a treatment procedure via the display 118 and/or an evaluation/feedback algorithm 124. In some embodiments, the console 104 can include a processing device (not shown) having processing circuitry, e.g., a microprocessor. The processing device can be configured to execute stored instructions relating to the control algorithm 122 and/or the evaluation/feedback algorithm 124. Furthermore, the console 104 can be configured to communicate with the treatment device 102, e.g., via the cable 106. For example, the therapeutic element 110 of the treatment device 102 can include a sensor (not shown) (e.g., a recording electrode, a temperature sensor, a pressure sensor, or a flow rate sensor) and a sensor lead (not shown) (e.g., an electrical lead or a pressure lead) configured to carry a signal from the sensor to the handle 108. The cable 106 can be configured to carry the signal from the handle 108 to the console 104.

The console 104 can have different configurations depending on the treatment modality of the treatment device 102. For example, when the treatment device 102 is configured for electrode-based or transducer-based treatment, the console 104 can include an energy generator (not shown) configured to generate RF energy, pulsed RF energy, microwave energy, optical energy, focused ultrasound energy (e.g., HIFU), direct heat energy, or another suitable type of energy. In some embodiments, the console 104 can include an RF generator operably coupled to one or more electrodes (not shown) of the therapeutic element 110. When the treatment device 102 is configured for cryotherapeutic treatment, the console 104 can include a refrigerant reservoir (not shown) and can be configured to supply the treatment device 102 with refrigerant, e.g., pressurized refrigerant in liquid or substantially liquid phase. Similarly, when the treatment device 102 is configured for chemical-based treatment, the console 104 can include a chemical reservoir (not shown) and can be configured to supply the treatment device 102 with the chemical. In certain embodiments, the therapeutic assembly may further include one or more thermoelectric devices (such as a Peltier device) for the application of heat or cold therapy. Any energy modality can either be used alone or in combination with other energy modalities. In some embodiments, the treatment device 102 can include an adapter (not shown) (e.g., a luer lock) configured to be operably coupled to a syringe (not shown). The adapter can be fluidly connected to a lumen (not shown) of the treatment device 102, and the syringe can be used, for example, to manually deliver one or more chemicals to the treatment location, to withdraw material from the treatment location, to inflate a balloon (not shown) of the therapeutic element 110, to deflate a balloon of the therapeutic element 110, or for another suitable purpose. In other embodiments, the console 104 can have other suitable configurations.

Upon delivery to a target site, the therapeutic assembly may be further configured to be deployed into a treatment state or arrangement for delivering energy at the treatment site. In some embodiments, the therapeutic assembly may be placed or transformed into the deployed state or arrangement via remote actuation, for example, via an actuator, such as a knob, pin, or lever carried by the handle. In other embodiments, however, the therapeutic assembly may be transformed between the delivery and deployed states using other suitable mechanisms or techniques. The monitoring system can provide feedback of parameters such as nerve activity to verify that the treatment assembly provided therapeutically effective treatment.

In the deployed state, the therapeutic assembly can be configured to contact an inner wall of a vessel and to carry out ablation or a series of ablations without the need for repositioning. For example, the therapeutic element can be configured to create a single lesion or a series of lesions, e.g., overlapping or non-overlapping. In some embodiments, the lesion or pattern of lesions can extend around generally the entire circumference of the vessel, but can still be non-circumferential at longitudinal segments or zones along a lengthwise portion of the vessel. This can facilitate precise and efficient treatment with a low possibility of vessel stenosis. In other embodiments, the therapeutic element can be configured cause a partially-circumferential lesion or a fully-circumferential lesion at a single longitudinal segment or zone of the vessel.

The proximal end of the therapeutic assembly is carried by or affixed to the distal portion of the elongate shaft. A distal end of the therapeutic assembly may terminate with, for example, a rounded tip or cap. Alternatively, the distal end of the therapeutic assembly may be configured to engage another element of the system or treatment device. For example, the distal end of the therapeutic assembly may define a passageway for engaging a guide wire (not shown) for the delivery of the treatment device using over-the-wire (OTW) or rapid exchange (RX) techniques. If the treatment device and the sampling component are part of a single intervention device, the intervention device may include one or more filters or testing media for in-system analysis of sample cells.

The monitoring system may include one or more energy sources (for example, a coolant reservoir and/or an RF generator), which may be housed in a console or used as a stand-alone energy source. The console or energy source is configured to generate a selected form and magnitude of energy for delivery to the target treatment site via the therapeutic assembly. A control mechanism such as a foot pedal may be connected to the console to allow the operator to initiate, terminate, and optionally to adjust various operational characteristics of the energy generator, including, but not limited to, power delivery. The system may also include a remote control device (not shown) that can be positioned in a sterile field and operably coupled to the therapeutic assembly. In other embodiments, the remote control device is configured to allow for selective activation of the therapeutic assembly. In other embodiments, the remote control device may be built into the handle assembly. The energy source can be configured to deliver the treatment energy via an automated control algorithm and/or under the control of the clinician. In addition, the energy source or console may include one or more evaluation or feedback algorithms to provide feedback to the clinician before, during, and/or after therapy. The feedback can be based on output from the monitoring system.

The energy source can further include a device or monitor that may include processing circuitry, such as one or more microprocessors, and a display. The processing circuitry can be configured to execute stored instructions relating to the control algorithm. The energy source may be configured to communicate with the treatment device to control the treatment assembly and/or to send signals to or receive signals from the monitoring system. The display may be configured to provide indications of power levels or sensor data, such as audio, visual, or other indications, or may be configured to communicate the information to another device. For example, the console may also be operably coupled to a catheter lab screen or system for displaying treatment information, including for example nerve activity before and after treatment, effects of ablation or temperature therapy, lesion location, lesion size, etc.

The distal end of one embodiment of a treatment device includes a distal electrode which is used to apply energy to the target cells (for example, RF energy or ultrasound energy), although a plurality of electrodes can instead be used. Alternatively or additionally, the distal end can include a light emitter such as a laser or LED diode, or a microwave antenna (not shown). The distal end can further include a radiopaque marker band for positioning the device.

The distal end of another embodiment of a treatment device includes a cryoballoon, which is used to cool (remove energy from) the target cells. In this embodiment, the distal end of the treatment device includes an inner balloon and an outer balloon, which may help prevent coolant leaks from the cryoballoon. If additional energy modalities are used, the cryoballoon may include one or more electrodes, antennas, or laser diodes, or LED diodes (not shown). The distal end may further include a radiopaque marker band for positioning the device.

One of ordinary skill in the art will recognize that the various embodiments described herein can be combined. The following examples are provided to better illustrate the disclosed technology and are not to be interpreted as limiting the scope of the technology. To the extent that specific materials are mentioned, it is merely for purposes of illustration and is not intended to limit the technology. One skilled in the art may develop equivalent means or reactants without the exercise of inventive capacity and without departing from the scope of the technology. It will be understood that many variations can be made in the procedures herein described while still remaining within the bounds of the present technology. It is the intention of the inventors that such variations are included within the scope of the technology.

EXAMPLES Example 1 Effect of RF Ablation and SNS Denervation on IL-10 Levels

Animals were broken into three groups of three animals each: naïve (no treatment), sham (catheterized but not ablated), and treated (subject to ablation at 65° C. and 90 seconds using a spiral ablation catheter device). Left and right renal arteries and surrounding tissue samples were obtained by sampling tissue in the area of ablation at 10 minutes (“day 0”), 24 hours, or 7 days post-treatment. Slices from the center of ablation sites were removed for histopathological analysis, and the ablation sites were cleaned up by removing any non-ablated tissue and pooled. Tissue was maintained during the dissection process using RNALater® solution.

Pooled tissue samples were weighed and mixed under frozen conditions, and then added to round-bottomed tubes containing 2× stainless steel beads (5 mm diameter) at room temperature. 900 μL QIAzol lysis reagent was added to each tube, and the tissue was macerated using the TissueLyser II Adaptor Set with disruption at 30 Hz (3×2 minutes) to release RNA. An additional 300 μL of lysis buffer was added to each tube, and the disruption cycle was repeated (1×2 minutes at 30 Hz). Lysates were transferred to new Eppendorf tubes for mRNA isolation.

120 μl gDNA Eliminator Solution was added to each lysate sample, and tubes were shaken vigorously for 15 seconds. 180 μL of chloroform was added, and tubes were again shaken vigorously for 15 seconds. After 2-3 minutes at room temperature, tubes containing homogenate were centrifuged at 12,000×g for 15 minutes at 4° C. The centrifuge was warmed to room temperature, and the upper aqueous phase was transferred to a new Eppendorf tube. An equal volume of 70% ethanol was added to each tube with thorough mixing, and 700 μL of each sample was transferred to an RNeasy Mini spin column in a 2 mL collection tube. Samples were centrifuged for 15 seconds at >8000×g (>10,000 rpm) at room temperature and flow-thru was discarded. The ethanol mixing and RNeasy centrifugation steps were repeated until all sample was used up. 700 μL of Buffer RWT was added to each spin column, followed by centrifugation for 15 seconds at >8,000×g (>10,000 rpm) to wash the membrane. Flow-thru was discarded, and 500 μL Buffer RPE was added each spin column, followed by centrifugation for 15 seconds at >8,000×g (>10,000 rpm). Flow thru was discarded, and 500 μl Buffer RPE was again added to each spin column, followed by centrifugation for 2 minutes at >8,000×g (>10,000 rpm) to wash the membrane. RNeasy spin columns were placed in a new 2 mL collection tube and centrifuged at full speed for 1 minute. The spin column was placed in a new 1.5 mL collection tube. 50 μL RNase free water was added directly to the spin column membrane, and RNA eluted was eluted by centrifugation for 1 minute at >8,000×g (>10,000 rpm). This step was repeated using another 50 μL of RNase free water. To ensure significance, A260 readings were verified to be greater than 0.15. An absorbance of 1 unit at 260 nm corresponds to 44 Mg of mRNA per mL (A260=1=44 μg/mL) at neutral pH.

ABI High Capacity cDNA kits were used to convert mRNA to cDNA for quantitative real-time PCR (qPCR). PCR was performed in optical 384-well plates, freshly prepared on the Eppendorf epMotion liquid handler. Final reaction volume was 20 μL (4 μL Taqman Assay+mixture of 6 μL cDNA (3 ng)+10 μL Universal Master Mix with UNG). Assays were performed to include +RT (reverse transcriptase) samples and, when appropriate, a −RT control. Endogenous controls (×2) were run in triplicate and animal samples were run only once for screening purposes. The real-time PCR protocol included an initial step of 50° C. (2 minutes) to activate the DNA polymerase, denaturation by a hot start at 95° C. for 10 minutes, and 40 cycles of a two step program (denaturation at 95° C. for 15 seconds for primer annealing/extension at 60° C. for 1 minute). Fluorescence data was collected at 60° C. Fluorescence was quantified with the ABI PRISM 7900HT, and the resultant data was analyzed using SDS RQ Manager (1.2.1) Software (Sequence Detection System Software, Applied Biosystems). Each biomarker was checked, and threshold and baseline was adjusted to produce (in Δ Rn versus Cycle) an amplification curve of the type suggested by Applied Biosystems in their “Relative Quantification Using Comparative Ct Getting Started Guide.” A calibrator was selected for calculation of the RQ (relative quantification). The calibrator was based on an average of 6× figures from the three naïve animals, left & right arteries, resulting in a numerical result of 1 for the naïve RQ. For calculation of the RQ for the standard deviation (SD) of the naïves, any other experimental animal was used as a calibrator (generally the first animal for Day 0 treated). RQ averages of animals (×3) in the same treatment group were calculated for each point and for each biomarker individually, and plotted in bar graphs.

Renal NE and dopamine (DBN) levels in naïve, sham, and test animals were evaluated at 10 minutes, 24 hours, and 7 days. Average kidney NE production post-ablation is shown in FIG. 5.

The initial screen was carried out using 70 candidate biomarkers. IL-10 exhibited a significant increase in expression at 10 minutes, 24 hours, and 7 days post-ablation (FIGS. 6A-6C).

Example 2 Effect of Heat and Inflammation Exposure on IL-10 Levels

The effect of heat and inflammation on IL-10 expression was evaluated in human primary vascular cells (Human Coronary Artery Endothelial Cells (HCAEC) and Human Coronary Artery Smooth Muscle Cells (HCASMC)) and neuronal cells (LUHMES neuronal cells).

Cells were grown according to vendor instructions to an apparent density of 1×10⁶ in seven individual T175 flasks. Four experimental arms were utilized: (1) control (no heat, no inflammation), (2) inflammation only (cells pre-incubated with IL-1 and TNFα for one hour to invoke slight inflammatory response), (3) heat plus inflammation (one hour pre-incubation with IL-1 and TNFα followed by 90 seconds at 60° C. and a one minute recovery at room temperature), and (4) heat plus inflammation (one hour pre-incubation with IL-1 and TNFα followed by three 90 second pulses at 60° C. and a five minute recovery at room temperature).

Following treatment, cell monolayers were washed two times with serum-free media, rinsed once with 1×PBS, and rinsed with 3 mL pre-trypsin rinse. Rinsed cells were exposed to 3 mL trypsin for three minutes at 37° C., followed by neutralization with 7 mL serum-free cell media. Cells were detached from the flask in a total volume of 10 mL, transferred to a 15 mL conical Falcon tube, and pelleted at 12,000×g for five minutes. Growth medium was discarded and pellets were lysed with Qiagen RLT lysis buffer containing BME.

For RNA isolation, 1,200 μL of RLT lysis buffer was added to each pellet. Cells were defrosted slowly at 37° C. in the presence of the lysis buffer and pipetted up and down as soon as possible. The lysate was centrifuged for 3 minutes at 14,000 rpm, and the supernatant was removed. One volume of 70% ethanol was added to the lysate, and the mixture was stirred by pipetting. Up to 700 μL of sample was transferred to an RNeasy Mini spin column placed in a 2 mL collection tube. The column was centrifuged for 15 seconds at ≧8,000×g (≧10,000 rpm), and flow through was discarded.

For DNase digestion, 350 μL Buffer RWI was added to each column, followed by centrifugation for 15 seconds at ≧8,000×g (≧10,000 rpm). Flow through was discarded. 10 μL DNase 1 stock solution was added to 70 μL Buffer RDD, and this solution was mixed by inversion and briefly centrifuged. 80 μL of the DNase 1 incubation mix was added directly to the column membrane, which was then left on the benchtop for 15 minutes. 350 μL Buffer RWI was added to the column, followed by centrifugation for 15 seconds at ≧8,000×g (≧10,000 rpm). Flow through was discarded, and 500 μL Buffer RPE was added, followed by centrifugation for 15 seconds at ≧8,000×g (≧10,000 rpm). This step was repeated, and the spin column was placed into a new 2 mL collection tube and centrifuged at full speed for one minute to dry the membrane. The spin column was placed into a new 1.5 mL collection tube, and 30-50 μL RNase-free water was added. This step was repeated, and RNA levels were measured by Abs₂₆₀/Abs₂₈₀ ratio on a Wallac plate reader.

For cDNA preparation, Genomic DNA Elimination Mixture was prepared by adding 2.0 μL GE (5×gDNA eliminator buffer) to each 8.0 μL RNA sample in a PCR plate and mixing gently with a pipettor. After a brief centrifugation, cells were incubated at 42° C. for 5 minutes and chilled on ice immediately for at least one minute. RT Cocktail was prepared by mixing 16 μL BC3 (5×RT Buffer 3), 4 μL P2 (Primer & External Control Mix), 8 μL RE3 (RT Enzyme Mix 3), and 12 μL water. For the first strand cDNA synthesis reaction, 10 μL RT cocktail was added to each 10 μL Genomic DNA Elimination Mix (×8) and mixed gently, followed by incubation at 42° C. for 15 minutes. The reaction was stopped by heating at 95° C. for five minutes, and 91 μL of water was added to each 20 μL of cDNA synthesis reaction.

SA Biosciences plates were used for gPCR. PCR components mix was prepared by mixing 593 μL SYBR Green Master Mix, 110 μL cDNA synthesis reaction, and 483 μL RNase-free water, mixing gently, spinning at high speed, and then allow the mixture to site for at least ten minutes. PCR Arrays were carefully removed from their sealed bags, and PCR components were mixed into the plates at a volume of at least 10 μL per well using Eppendorf epMotion 5075. Plates used for testing included one or more of RT² Profiler PCR Arrays selected from Human Apoptosis (PAHS-012E-4), Human Cytokines & Chemokines (PAHS-150E-4), Human Endothelial Cell Biology (PAHS-015E-4), Human Hypertension (PAHS-037E-4), and Human Neurotoxicity (PAHS-096E-4). Arrays were tightly sealed with Optical Adhesive Film, centrifuged for two minutes at 1,000×g at room temperature to remove bubbles, and placed on ice until ready to run. Plates were run under “Absolute Quantification” conditions (1×10 minutes at 95° C., 40×15 seconds at 95° C., 1×1 minute at 60° C.) using the set recommended by SABiosciences.

Results are summarized in Table 1. Data was sorted according to Fold Change values, which represent the expression ratio between Control and Treated samples. A positive value indicates a gene that was upregulated, while a negative value indicates a gene that was downregulated. IL-10 exhibited a significant increase in expression following treatment with heat and inflammation, while exhibiting only a slight increase in response to inflammation only (FIG. 8). This differed from the expression pattern observed for other inflammation inhibitors. IL-7, IFNB1, IL-11, CXCL2, CXCL11, and CASP7 each exhibited a significant increase in expression following exposure to inflammatory conditions (FIGS. 9-13 and 15, respectively). However, when heat was applied in addition to inflammatory conditions, each of these molecules exhibited a drop in expression levels versus inflammatory conditions only, with expression levels often comparable to baseline control levels (i.e., absence of heat or inflammatory conditions). CD70 and CASP10 were both expressed at levels comparable to or slightly less than the control in the presence of inflammatory conditions, with a significant reduction in expression versus control levels in the presence of heat and inflammation (FIGS. 14 and 16, respectively). Overall, IL-10 was the only inflammation inhibitor tested that exhibited a significant increase in expression in the presence of heat regardless of whether inflammatory conditions were present.

TABLE 1 Heat + Control Heat + inflammation (no heat, Inflam- inflammation (3 cycles, no inflam- mation (1 minute 5 minute Gene Cell type mation) only recovery) recovery) IL-10 HCASMC 0.769 1 1.871 2.1855 CXCL11 HCASMC 0.5884 1 0.4109 0.4056 CXCL2 HCASMC 0.21 1 0.4755 0.3719 IL-11 HCASMC 0.311 1 0.3385 0.4521 IFNB1 HCAEC 0.4793 1 0.4681 0.3321 IL-7 HCAEC 0.021 1 0.4518 0.4422 CD70 LUHMES 1.2135 1 0.4164 0.4479 CASP10 LUHMES 1.0757 1 0.1979 0.2129 CASP7 LUHMES 0.4504 1 0.4361 0.496

Additional Examples

1. A method for increasing IL-10 expression level at or near a target site in a human subject, the method comprising performing a thermal ablation procedure at or near the target site, wherein the thermal ablation procedure results in an increase in IL-10 expression level at or near the target site.

2. A method for inhibiting inflammation at or near a target site in a human subject, the method comprising performing a thermal ablation procedure at or near the target site, wherein the thermal ablation procedure results in an increase in IL-10 expression level at or near the target site, wherein the increase in IL-10 expression inhibits inflammation.

3. A method for treating an inflammatory condition in a human subject, the method comprising performing a thermal ablation procedure, wherein the thermal ablation procedure results in an increase in IL-10 expression level, and wherein the increase in IL-10 expression inhibits inflammation.

4. The method of any of examples 1-3 wherein IL-10 expression level is increased within 30 minutes or less following the thermal ablation procedure.

5. The method of example 4 wherein IL-10 expression level is increased within 10 minutes or less following the thermal ablation procedure.

6. The method of any of examples 1-3 wherein IL-10 expression level is increased at one or more timepoints selected from 10 minutes, 24 hours, and 7 days following the ablation procedure.

7. The method of any of examples 1-3 wherein the thermal ablation procedure is carried out using a modality selected from the group consisting of monopolar or bipolar radio frequency (RF) energy, microwave energy, laser or optical light energy, ultrasound energy, magnetic energy, direct heat energy, and cryotherapeutic energy.

8. The method of any of examples 1-3 wherein the target site is in a renal blood vessel of the human subject.

9. The method of example 8 wherein the thermal ablation procedure targets renal sympathetic nerves.

10. A device for carrying out the method of any of examples 1-9.

CONCLUSION

The above detailed descriptions of embodiments of the technology are not intended to be exhaustive or to limit the technology to the precise form disclosed above. Although specific embodiments of, and examples for, the technology are described above for illustrative purposes, various equivalent modifications are possible within the scope of the technology, as those skilled in the relevant art will recognize. For example, while steps are presented in a given order, alternative embodiments may perform steps in a different order. The various embodiments described herein may also be combined to provide further embodiments. All references cited herein are incorporated by reference as if fully set forth herein.

From the foregoing, it will be appreciated that specific embodiments of the technology have been described herein for purposes of illustration, but well-known structures and functions have not been shown or described in detail to avoid unnecessarily obscuring the description of the embodiments of the technology. Where the context permits, singular or plural terms may also include the plural or singular term, respectively.

Moreover, unless the word “or” is expressly limited to mean only a single item exclusive from the other items in reference to a list of two or more items, then the use of “or” in such a list is to be interpreted as including (a) any single item in the list, (b) all of the items in the list, or (c) any combination of the items in the list. Additionally, the term “comprising” is used throughout to mean including at least the recited feature(s) such that any greater number of the same feature and/or additional types of other features are not precluded. It will also be appreciated that specific embodiments have been described herein for purposes of illustration, but that various modifications may be made without deviating from the technology. Further, while advantages associated with certain embodiments of the technology have been described in the context of those embodiments, other embodiments may also exhibit such advantages, and not all embodiments need necessarily exhibit such advantages to fall within the scope of the technology. Accordingly, the disclosure and associated technology can encompass other embodiments not expressly shown or described herein. 

1. A method for increasing IL-10 expression level at or near a target site in a human subject, the method comprising performing a thermal ablation procedure at or near the target site, wherein the thermal ablation procedure results in an increase in IL-10 expression level at or near the target site.
 2. A method for inhibiting inflammation at or near a target site in a human subject, the method comprising performing a thermal ablation procedure at or near the target site, wherein the thermal ablation procedure results in an increase in IL-10 expression level at or near the target site, wherein the increase in IL-10 expression inhibits inflammation.
 3. A method for treating an inflammatory condition in a human subject, the method comprising performing a thermal ablation procedure, wherein the thermal ablation procedure results in an increase in IL-10 expression level, and wherein the increase in IL-10 expression inhibits inflammation.
 4. The method of claim 2 wherein IL-10 expression level is increased within 30 minutes or less following the thermal ablation procedure.
 5. The method of claim 4 wherein IL-10 expression level is increased within 10 minutes or less following the thermal ablation procedure.
 6. The method of claim 2 wherein IL-10 expression level is increased at one or more timepoints selected from 10 minutes, 24 hours, and 7 days following the ablation procedure.
 7. The method of claim 2 wherein the thermal ablation procedure is carried by a modality selected from the group consisting of monopolar or bipolar radio frequency energy, microwave energy, laser light or optical energy, ultrasound energy, magnetic energy, direct heat energy, and cryotherapeutic energy.
 8. The method of claim 2 wherein the target site is in a renal blood vessel of the human subject.
 9. The method of claim 8, wherein the thermal ablation procedure targets renal sympathetic nerves.
 10. A device for carrying out the method of claim
 1. 